phd entrance
TRANSCRIPT
MEWAR UNIVERSITY
Detailed Syllabus of Ph.D. & M.Phil. Entrance Examination
1. Computer Science
2. Mechanical Engineering
3. Electrical Engineering
4. Civil Engineering
5. Environmental
6. Electronics
7. Management
8. Commerce
9. Physics
10. Chemistry
11. Mathematics
12. Bio & Life Sciences
13. Education
14. Law
15. English
16. Sanskrit
17. Visual Arts
18. Library Science
19. Hindi
20. Psychology
21. Public Administration
22. Geography
23. History
24. Political Science
1. Computer Science
Discrete Structures
Sets, Relations, Functions. Pigeonhole Principle, inclusion-Exclusion Principle,
Equivalence and Partial Orderings, Elementary counting techniques, Probability
Measures for information and Mutual information.
Computability: Model of computation-Finite Automata, Pushdown Automata, Non-
determinism and NFA, DPDA and PDAs and language accepted by these structures,
Grammar, Languages, non-compatibility and Example of non-Computable problems.
Graph: Definition, walks, paths, trails, connected graphs, regular and bipartite graphs,
cycles and circuits. Tree and rooted tree. Spanning trees. Eccentricity of a vertex radius
and diameter of a graph, Central Graphs, Center(s) of a tree Hamiltonian and Eulerian
Computer Arithmetic
Prepositional (Boolean) Logic, Predicate Logic, Well-formed formulae (WFF)
Satisfiability and tautology.
Logic Families: TTL, ECL and C-MOS gates. Boolean algebra and minimization of
Boolean functions. Flip-flops-types, race condition and comparison. Design of
combinational and sequential circuits.
Representation of Integers: Octal, Hex. Decimal and Binary. 2's complement and 1’s
complement arithmetic. Floating-point representation.
Programming in C and C++
Programming in C: Elements of C- Tokens, identifiers, data types in C. Control
structures in C. Sequence, selection and iteration(s). Structured data types, arrays, structure,
union, string, and pointers.
OO Programming Concepts: Class, Object, Instantiation, Inheritance, Polymorphism and
Overloading.
Relational Database Design and SQL
E-R Diagrams and their transformation to relational design, Normalization-NF, 2NF,
3NF, BCNF and 4NF. Limitations of 4NF and BCNE.
SQL: Data Definition Language (DLL). Data Manipulation Language (DML), Data
Control Language (DCL) commands. Database object like-Views, indexes, sequences,
synonyms, data dictionary.
Computer Networks
Networks Fundamentals: Local Area Networks (LAN),Metropolitan Area Network
(MAN), Wide Area Networks (WAN), Wireless Networks, Inter Networks.
Reference Models: The OSI model, TCP/IP model.
Data Communication: Channel capacity, Transmission media-twisted pair, coaxial
cables, fiber -optic cables, wireless transmission-radio, microwave, infrared and
millimeter waves, Light wave transmission. Telephones-Local loop, trunks,
multiplexing, switching, narrowband ISDN, broadband ISDN, ATM, High speed
LANS. Cellular Radio. Communication satellites, Geosynchronous and low-orbit.
UNIX
The Unix System: File system, process management, bourne shell, shell variables,
command line programming.
Filters and Commands: Pr, head, tail, cut, paste, sort, uniq, tr, join, etc, grep, egrep,
fgrep, etc., sed, awk, etc.
System Calls (like): Create, open, close, read,write, iseek, link, Unlin,s tat, fstat, umask,
chmod, exec, fork, wait, system.
Software Engineering
System Development Life Cycles (SDLC): Steps. Water fall model, Prototypes, Spiral
model.
Software Metrics: Software Project Management
Software Design: System design, detailed design, function oriented design, object
oriented design, user interface design, design level metrics.
Coding and Testing: Testing level metrics. Software quality and reliability, Clean room
approach, software reengineering.
Current Trends and Technologies
The topics of current interest in Computer Science and Computer Applications shall be
covered. The experts shall use their judgment from time to time to include the topics of
popular interest, which are expected to be known for an application development
software professional, currently, they include:
2 Mechanical Engineering
1. Thermodynamics
Cycles and IC Engines, Basic concepts, Open and Closed systems. Heat and work. Zeroth, First
and Second Law, Application to non-Flow and Flow processes. Entropy, Availability,
Irreversibility and Tds relations. Claperyron and real gas equations, Properties of ideal gases
and vapours. Standard vapour, Gas power and Refrigeration cycles. Two stage compressor. C-
I and S.I. Engines. Pre-ignition, Detonation and Diesel-knock, Fuel injection and Carburation,
Supercharging.
2. Heat Transfer and Refrigeration and Air-conditioning.
Modes of heat transfer. One dimensional steady and unsteady conduction. Composite slab
and Equivalent Resistance. Heat dissipation from extended surfaces, Heat exchangers,
Overall heat transfer coefficient, Empirical correlations for heat transfer in laminar and
turbulent flows and for free and forced Convection, Thermal boundary layer over a flat plate.
Fundamentals of diffusive and connective mass transfer, Black body and basic concepts in
Radiation, Enclosure theory, Shape factor, Net work analysis. Heat pump and Refrigeration
cycles and systems, Refrigerants. Condensers, Evaporates and Expansion devices,
Psychometric, Charts and application to air conditioning, Sensible heating and cooling,
Effective temperature, comfort indices, Load calculations, Solar refrigeration, controls, Duct
design.
3. Fluid Mechanics:
Properties and classification of fluids, Manometry, forces on immersed surfaces, Center of
pressure, Buoyancy, Elements of stability of floating bodies. Kinematics and Dynamics.
Irrotational and incompressible. Inviscid flow. Velocity potential, Pressure field and Forces on
immersed bodies. Bernoulli’s equation, Fully developed flow through pipes, Pressure drop
calculations, Measurement of flow rate and Pressure drop. Elements of boundary layer
theory, Integral approach, Laminar and tubulent flows, Separations. Flow over weirs and
notches. Open channel flow, Hydraulic jump. Dimensionless numbers, Dimensional analysis,
Similitude and modelling. One-dimensional isentropic flow, Normal shock wave, Flow
through convergent – divergent ducts, Oblique shock-wave, Rayleigh and Fanno lines.
4. Fluid Machinery and Steam Generators:
Performance, Operation and control of hydraulic Pump and impulse and reaction Turbines,
Specific speed, Classification. Energy transfer, Coupling, Power transmission, Steam
generators Fire-tube and water-tube boilers. Flow of steam through Nozzles and Diffusers,
Wetness and condensation. Various types of steam and gas Turbines, Velocity diagrams.
Partial admission. Reciprocating, Centrifugal and axial flow Compressors, Multistage
compression, role of Mach Number, Reheat, Regeneration, Efficiency, Governance.
5. THEORY OF MACHINES:
Kinematic and dynamic analysis of planer mechanisms. Cams. Gears and gear trains.
Flywheels. Governors. Balancing of rigid rotors and field balancing. Balancing of single and
multicylinder engines, Linear vibration analysis of mechanical systems. Critical speeds and
whirling of shafts Automatic controls.
6. MACHINE DESIGN:
Design of Joints : cotters, keys, splines, welded joints, threaded fasteners, joints formed by
interference fits. Design of friction drives : couplings and clutches, belt and chain drives,
power screws.
Design of Power transmission systems : gears and gear drives shaft and axle, wire ropes.
Design of bearings : hydrodynamics bearings and rolling element bearings.
7. STRENGTH OF MATERIALS:
Stress and strain in two dimensions, Principal stresses and strains, Mohr’s construction, linear
elastic materials, isotropy and anisotropy, stress-strain relations, uniaxial loading, thermal
stresses.
8. ENGINEERING MATERIALS:
Basic concepts on structure of solids. Crystalline maferials. Detects in crystalline materials.
Alloys and binary phase diagrams. Structure and properties of common engineering
materials. Heat treatment of steels. Plastics, Ceramics and composite materials. Common
applications of various materials.
9. PRODUCTION ENGINEERING:
Metal Forming : Basic Principles of forging, drawing and extrusion; High energy rate forming;
Powder metallurgy.
Fabrication Processes : Principles of Gas, Arc, Shielded arc Welding; Advanced Welding
Processes, Weldability: Metallurgy of Welding.
Metal Cutting : Turning, Methods of Screw Production, Drilling, Boring, Milling, Gear
Manufacturing, Production of flat surfaces, Grinding & Finishing Processes. Computer
Controlled Manufacturing Systems-CNC, DNC, FMS, Automation and Robotics.
10. INDUSTRIAL ENGINEERING:
Production Planning and Control : Forecasting – Moving average, exponential smoothing,
Operations, scheduling; assembly line balancing, Product development, Break-even analysis,
Capacity planning, PERT and CPM.
11. ELEMENTS OF COMPUTATION:
Computer Organization, Flow charting, Features of Common computer Languages –
FORTRAN, d Base III, Lotus 1-2-3, C and elementary Programming.
3 Electrical Engineering
Group-I: POWER SYSTEM
Transmission line parameters; Representation of short, medium, and long transmission
lines – ABCD parameters; Circle Diagram; Per Unit representation; 3-Φ system; Short
Circuit Studies; Sequence Networks; Load-flow Studies – Gauss Seidel method, Newton-
Raphson Method; Automatic Generation Control; Load-Frequency Control; Automatic
Voltage Regulator;
Group-II: POWER ELECTRONICS AND DRIVES Group
Characteristics and ratings of different thyristor family devices, their turn on and turn off
methods with their protection, series and parallel connection of SCRs and their derating,
controlled single phase and three phase rectifiers for different types of load viz. R, R-L,
R-L-E, single phase and three phase voltage source and current source inverter,
Group-III: COMPUTER TECHNOLOGY Group
Soft Computing (Basics of neural network, fuzzy logic, genetic algorithm, wavelets).
Digital Electronics: Adder/Subtractor, Multiplexer/Demultiplexer, Serial and parallel
operations; Computer and its Applications: Fundamentals of Computer Architecture
(representation of information, control unit, bus organisation, memory, I/O devices),
ObjectOriented programming(classes and objects, inheritance, polymorphism),
Fundamentals of Operating Systems (Operating System Structure, management of
resources), Fundamentals of Data Communication and Networks.
Group-IV: CONTROL AND INSTRUMENTATION Group
Mathematical Molding of physical systems, Transfer function of linear systems, Steady
state errors and error constants, static error coefficients Time domain analysis, Stability of
control system, Routh-Hurwitz’s stability criterion. Root locus plots, analysis of control
system by root loci. Relationship between time and frequency response, Polar plot,
Bode’s Plot, Nyquist plot and Nyquist stability criterion, Relative Stability, Phase and
Gain Margins, Constant M and N circle. Design of Feedback Controllers: Design of
Group-V: ELECTRONICS AND COMMUNICATION Group
Biasing and bias stability of transistor and FET amplifiers. Amplifiers: single-and multi-
stage, differential and operational, feedback, and power. Frequency response of
amplifiers. Simple op-amp circuits. Filters. Function generators and wave-shaping
circuits, 555 Timers. Power supplies. Logic gates; digital IC families (DTL, TTL, ECL,
MOS, CMOS). Combinatorial circuits: arithmetic circuits, code converters, multiplexers,
decoders, PROMs and PLAs. Sequential circuits: latches and flip-flops, counters and
shift-registers. Sample and hold circuits, ADCs, DACs. Operational Amplifiers and other
analog ICs., Semiconductor memories. Microprocessor(8085): architecture, programming
and I/O interfacing.
4 Civil Engineering
Advanced Structural Mechanics, Finite Element Analysis, Advanced Theory and
Design of Concrete Structures, Structural Dynamics, Theory and Design of Plates
and Shells, Prestressed Concrete Design, Stability of Structures, Earthquake Engg
Advanced and Applied Soil Mechanics, Advanced Foundation Engineering,
Geosynthetics, Soil Dynamics, FEM and constitutive Modeling in Geomechanics,
Reinforced Soil Structures, Soil Exploration and Field Testing, Earthquake
Geotechnical Engineering, Ground Improvement Techniques
Applied Hydraulic Engineering, Surface Water Hydrology, Groundwater Engineering,
Water Resources Planning and Management, Irrigation Technology, Unsteady
Open-Channel Flows
Analysis and Design of Pavements, Urban Transportation Planning, Traffic
Engineering and Management, Pavement Materials and Evaluation, Airport Planning
and Design, Geometric Design of Highways, GIS and Remote Sensing
Environmental Chemistry and Microbiology, Physico-Chemical Process for Water
and Wastewater Treatment, Biological Process Design for Wastewater Treatment,
Air Quality Management, Environmental Impact Assessment, Solid Waste
Management
5 Environmental
1. Definition, principles and scope of environmental science.
2. Ancient agenda for Environment as reflected in Sanskrit.
3. Environmental ethics, education and awareness role of youth, communities,
professional, planners, decision makers and implementers.
4. Basic of Atmospheric Science and Biosphere:
(A) ATMOSPHERE (B) INTRODUCTION TO OCEAN
5. Basics of lithosphere, hydrosphere and biosphere.
6. Fundamentals of Ecology, Definition, Subdivisions.
7. Biogeochemical cycles, food chain and food web.
8. Habitat : Freshwater, marine, estuarine and terrestrial ecosystems.
9. Geographical classification and zones natural resources, conservation and
sustainable development.
10. Concept and Scope of Environmental Chemistry :
Definition and explanation for various terms, segments of environment.
26 principles and cyclic pathways in the environments.
11. Chemistry of Biologically Important Molecules :
Chemistry of Water : Unusual physical properties, hydrogen bonding in
biological systems, unusual solvent properties, changes in water properties by
addition of solute. Protein structure and biological functions, enzymes, enzyme
metabolism, biosynthesis of DNA and RNA, mutations and Gene control during
embryogenesis.
12. Soil Chemistry : Formation, constituents and properties of soils, adsorption of
contaminants in soil.
13. Environmental Microbiology : Microbes – classification and their applications
in the environmental sciences. Cultivation and growth of microorganisms. Microorganisms
and their association with man, animals and plants. Microbes as anti-microbial agents,
Extremophilic microorganisms, Microbial metabolism.
14. Biomes and Habitat Diversity : Classification of biomes, major biotic elements
of each biome and their characteristics.
15. Biological diversity of India : Definition and nature, India’s biogeographically
history, physiography, climate and its impact on biodiversity. Indian forest and vegetation
types and diversity of flora and fauna.
16. Population and Community Ecology.
17. Wetlands Forests and Semi-arid Habitats of India : Definition and types of
wetlands, important wetlands of India and their conservation issues. Forests and semi-
arid habitats of India : their distribution in India, ecological status of forests and arid
lands, and their conservation.
The Earth Systems and Biosphere : Conservation of matter in various geo-spheres –
lithosphere, hydrosphere, atmosphere and biosphere. Energy budget of the earth. Earth’s
thermal environment and seasons. Ecosystem flow of energy and matter. Coexistence in
communities – food webs. Earth’s major ecosystem-terrestrial and aquatic. General
relationship between landscape, biomes and climate. Climates of India, Indian Monsoon,
El Nino. Tropical Cyclones and Western Disturbances.
18. Noise Pollution : Types, sources and consequences. Sampling Methods.
19. Radio-active Pollution : Types, sources and consequences. Sampling methods.
s for different type of projects.
Review of methodologies of EIA. Introduction to Check list, Matrix & Network methods for
EIA.
Prediction of short & long term Impacts on environment (physical, biological & socio
culture).
**20. Current Developments in the Subject.
6 Electronics
7 Management
8 Commerce
9. Physics
I. Mathematical Methods of Physics
Dimensional analysis; Vector algebra and vector calculus; Linear algebra, matrices, Cayley
Hamilton theorem, eigenvalue problems; Linear differential equations; Special functions
(Hermite, Bessel, Laguerre and Legendre); Fourier series, Fourier and Laplace transforms;
Elements of complex analysis: Laurent series-poles, residues and evaluation of integrals.
II. Classical Mechanics
Newton’s laws; Phase space dynamics, stability analysis; Central-force motion; Two-body
collisions, scattering in laboratory and centre-of-mass frames; Rigid body dynamics, moment
of inertia tensor, non-inertial frames and pseudoforces; Variational principle, Lagrangian and
Hamiltonian formalisms and equations of motion; Poisson brackets and canonical
Transformations.
III. Electromagnetic Theory
Electrostatics: Gauss’ Law and its applications; Laplace and Poisson equations, boundary
value problems; Magnetostatics: Biot-Savart law, Ampere's theorem, electromagnetic
induction; Maxwell's equations in free space and linear isotropic media; boundary conditions
on fields at interfaces; Scalar and vector potentials; Gauge invariance; Electromagnetic waves
in free space, dielectrics, and conductors.
IV. Quantum Mechanics
Wave-particle duality; Wave functions in coordinate and momentum representations;
Commutators and Heisenberg's uncertainty principle; Matrix representation; Dirac’s bra and
ket notation; Schroedinger equation (time-dependent and time-independent); Eigenvalue
problems such as particle-in-a-box, harmonic oscillator, etc.; Tunneling through a barrier;
Motion in a central potential; Orbital angular momentum.
V. Electronics
Semiconductor device physics, including diodes, junctions, transistors, field effect devices,
homo and heterojunction devices, device structure, device characteristics, frequency
dependence and applications; Optoelectronic devices, including solar cells, photodetectors,
and LEDs; High-frequency devices, including generators and detectors; Operational
amplifiers and their applications; Digital techniques and applications (registers, counters,
comparators and similar circuits); A/D and D/A converters; Microprocessor and
microcontroller basics.
10 Chemistry
Physical Chemistry:
1. Basic principles and applications of quantum mechanics – hydrogen atom,
angular momentum.
2. Variational and perturbational methods.
3. Basics of atomic structure, electronic configuration, shapes of orbitals, hydrogen
atom spectra.
4. Theoretical treatment of atomic structures and chemical bonding.
5. Chemical applications of group theory.
6. Basic principles and application of spectroscopy – rotational, vibrational,
electronic, Raman, ESR, NMR.
7. Chemical thermodynamics.
8. Phase equilibria.
Inorganic Chemistry
1. Chemical periodicity
2. Structure and bonding in homo- and heteronuclear molecules, including shapes of
molecules.
3. Concepts of acids and bases.
4. Chemistry of the main group elements and their compounds. Allotropy, synthesis,
bonding and structure.
5. Chemistry of transition elements and coordination compounds – bonding theories,
spectral and magnetic properties, reaction mechanisms.
6. Inner transition elements – spectral and magnetic properties, analytical
applications.
Organic Chemistry
1. IUPAC nomenclature of organic compounds.
2. Principles of stereochemistry, conformational analysis, isomerism and chirality.
3. Reactive intermediates and organic reaction mechanisms.
4. Concepts of aromaticity.
5. Pericyclic reactions.
6. Named reactions.
7. Transformations and rearrangements.
8. Principles and applications of organic photochemistry. Free radical reactions.
Interdisciplinary topics
1. Chemistry in nanoscience and technology.
2. Catalysis and green chemistry.
3. Medicinal chemistry.
4. Supramolecular chemistry.
5. Environmental chemistry.
11 Mathematics
UNIT – 1
Analysis: Elementary set theory, finite, countable and uncountable sets, Real number
system as a complete ordered field, Archimedean property, supremum, infimum.
Sequences and series, convergence, limsup, liminf. Bolzano Weierstrass theorem, Heine
Borel theorem. Continuity, uniform continuity, differentiability, mean value theorem.
Sequences and series of functions, uniform convergence.
Linear Algebra: Vector spaces, subspaces, linear dependence, basis, dimension, algebra
of linear transformations.
Algebra of matrices, rank and determinant of matrices, linear equations. Eigenvalues and
eigenvectors, Cayley-Hamilton theorem. Matrix representation of linear transformations.
Change of basis, canonical forms, diagonal forms, triangular forms, Jordan forms.
UNIT – 2
Complex Analysis: Algebra of complex numbers, the complex plane, polynomials,
Power series, transcendental functions such as exponential, trigonometric and hyperbolic
functions. Analytic functions, Cauchy-Riemann equations. Contour integral, Cauchy’s
theorem, Cauchy’s integral formula, Liouville’s theorem, Maximum modulus principle,
Schwarz lemma, Open mapping theorem. Taylor series, Laurent series, calculus of residues.
UNIT – 3
Ordinary Differential Equations (ODEs):
Existence and Uniqueness of solutions of initial value problems for first order ordinary
differential equations, singular solutions of first order ODEs, system of first order ODEs.
General theory of homogenous and non-homogeneous linear ODEs, variation of
parameters, Sturm-Liouville boundary value problem, Green’s function.
Partial Differential Equations (PDEs):
Lagrange and Charpit methods for solving first order PDEs, Cauchy problem for first order
PDEs. Classification of second order PDEs, General solution of higher order PDEs with
constant coefficients, Method of separation of variables for Laplace, Heat and Wave
equations.
UNIT – 4
Descriptive statistics, exploratory data analysis. Sample space, discrete probability,
independent events, Bayes theorem. Random variables and distribution functions
(univariate and multivariate); expectation and moments. Independent random variables,
marginal and conditional distributions. Characteristic functions. Probability inequalities
(Tchebyshef, Markov, Jensen). Modes of convergence, weak and strong laws of large
numbers, Central Limit theorems (i.i.d. case).
Markov chains with finite and countable state space, classification of states, limiting
behaviour of n-step transition probabilities, stationary distribution.
UNIT – 4
Numerical Analysis :
Numerical solutions of algebraic equations, Method of iteration and Newton-Raphson
method, Rate of convergence, Solution of systems of linear algebraic equations using
Gauss elimination and Gauss-Seidel methods, Finite differences, Lagrange, Hermite and
spline interpolation, Numerical differentiation and integration, Numerical solutions of
ODEs using Picard, Euler, modified Euler and Runge-Kutta methods.
12 Bio & Life Sciences
1. MOLECULES AND THEIR INTERACTION RELAVENT TO BIOLOGY
A. Structure of atoms, molecules and chemical bonds.
B. Composition, structure and function of biomolecules (carbohydrates, lipids,
proteins, nucleic acids and vitamins).
C. Stablizing interactions (Van der Waals, electrostatic, hydrogen bonding,
hydrophobic interaction, etc.).
D. Principles of biophysical chemistry (pH, buffer, reaction kinetics,
thermodynamics, colligative properties).
E. Bioenergetics, glycolysis, oxidative phosphorylation, coupled reaction, group
transfer, biological energy transducers.
2. CELLULAR ORGANIZATION
A. Membrane structure and function: Structure of model membrane, lipid bilayer
and membrane protein diffusion, osmosis, ion channels, active transport, ion pumps,
mechanism of sorting and regulation of intracellular transport, electrical properties of
membranes.
B. Structural organization and function of intracellular organelles: Cell wall, nucleus,
mitochondria, Golgi bodies, lysosomes, endoplasmic reticulum, peroxisomes, plastids,
vacuoles, chloroplast, structure & function of cytoskeleton and its role in motility.
C. Organization of genes and chromosomes: Operon, interrupted genes, gene families,
structure of chromatin and chromosomes, unique and repetitive DNA, heterochromatin,
euchromatin, transposons.
D. Cell division and cell cycle: Mitosis and meiosis, their regulation, steps in cell cycle, and
control of cell cycle.
E. Microbial Physiology: Growth, yield and characteristics, strategies of cell division,
stress response.
3. FUNDAMENTAL PROCESSES
A. DNA replication, repair and recombination: Unit of replication, enzymes involved,
replication origin and replication fork, fidelity of replication, extrachromosomal
replicons, DNA damage and repair mechanisms.
B. RNA synthesis and processing: Transcription factors and machinery, formation of
initiation complex, transcription activators and repressors, RNA polymerases, capping,
elongation and termination, RNA processing, RNA editing, splicing, polyadenylation,
structure and function of different types of RNA, RNA transport.
C. Protein synthesis and processing: Ribosome, formation of initiation complex, initiation
factors and their regulation, elongation and elongation factors, termination, genetic code,
aminoacylation of tRNA, tRNA-identity, aminoacyl tRNA synthetase, translational
proof-reading, translational inhibitors, post- translational modification of proteins.
4. CELL COMMUNICATION AND CELL SIGNALING
A. Host parasite interaction: Recognition and entry processes of different
pathogens like bacteria, viruses into animal and plant host cells, alteration of host
cell behavior by pathogens, virus-induced cell transformation, pathogen-induced
diseases in animals and plants, cell-cell fusion in both normal and abnormal cells.
B. Cell signaling: Hormones and their receptors, cell surface receptor, signaling
through G-protein coupled receptors, signal transduction pathways, second
messengers, regulation of signaling pathways, bacterial and plant two-component
signaling systems, bacterial chemotaxis and quorum sensing.
C. Cellular communication: Regulation of hematopoiesis, general principles of cell
communication, cell adhesion and roles of different adhesion molecules, gap
junctions, extracellular matrix, integrins, neurotransmission and its regulation.
5. DEVELOPMENTAL BIOLOGY
A. Basic concepts of development: Potency, commitment, specification, induction,
competence, determination and differentiation; morphogenetic gradients; cell fate
and cell lineages; stem cells; genomic equivalence and the cytoplasmic
determinants; imprinting; mutants and transgenics in analysis of development.
B. Gametogenesis, fertilization and early development: Production of gametes,
cell surface molecules in sperm-egg recognition in animals; embryo sac
development and double fertilization in plants; zygote formation, cleavage,
blastula formation, embryonic fields, gastrulation and formation of germ layers in
animals; embryogenesis, establishment of symmetry in plants; seed formation
and germination.
C. Morphogenesis and organogenesis in animals: Cell aggregation and
differentiation in Dictyostelium; axes and pattern formation in Drosophila,
amphibia and chick; organogenesis – vulva formation in Caenorhabditis elegans;
eye lens induction, limb development and regeneration in vertebrates;
differentiation of neurons, post embryonic development-larval formation,
metamorphosis; environmental regulation of normal development; sex
determination.
D. Morphogenesis and organogenesis in plants: Organization of shoot and root
apical meristem; shoot and root development; leaf development and phyllotaxy;
transition to flowering, floral meristems and floral development in Arabidopsis
and Antirrhinum.
13 Education
14 Law
15 English
16 Sanskrit
17 Visual Arts
18 Library Science
19 Hindi
20 Psychology
21 Public Administration
22 Geography
23 History
24 Political Science